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Sharp EL-512: Lorentz Factor, Table, Geometric Mean, 3D Vectors

Spotlight: Commodore P50

RPN with HP 15C & DM32: Stack Register Arithmetic

Sharp EL-512: Lorentz Factor, Table, Geometric Mean, 3D Vectors

Blog entries now made in Windows 11.

Two Sharp calculators. Left: EL-510RN (current) and EL-512 from 1984

Today’s blog will feature the classic Sharp EL-512 from the 1980s. The Sharp EL-512 is a keystroke programming calculator. The EL-512 has four program slots with a memory of 128 programming steps. All programs on the EL-512 are “entered in the blind” and must be entered in full each time.

Program commands:

[ x ]: prompt for a number. When editing a program, we will need to enter a valid number to continue the program.

LOOK: Stops the program and shows the immediate results.

Memory and recall:

STO: Stores the number in the display to memory register 1-9

x → M: Store the number in the display to memory M

M+: add to memory M

RM: recall memory M

Kn:

After a clear or an arithmetic key, just recalls the contents of memory register 1-9.

After entering a number, multiplies the number in the display by the contents of the memory register 1-9 (like RCL× K#)

To recall a register without alteration, it is always safe to multiply the register by 1:

1 Kn #

My review from 2020:

https://edspi31415.blogspot.com/2020/09/retro-review-sharp-el-512-scientific.html

Lorenz Factor

LF = (√(1-v²/c²))⁻¹

c = Speed of light in a vacuum = 299,792,452 m/s

Program:

x²

299792458

x²

+/-

√

1/x

Examples:

v = 2.1E8 (2.1 * 10^8) m/s; Result: 1.401212716

v = 2,456,000 m/s; Result: 1.000033559

v = 1,000,000 m/s; Result: 1.060752

Table: Quadratic Polynomial

Generate a table using the function:

f(x) = K3 × x² + K2 × x + K1

where x increases by 1.

Before running the program, store the following:

x² coefficient: K3

x coefficient: K2

constant coefficient: K1

beginning value: Subtract 1, then store the starting value in M. For example, if we want to start with x = 1, store 0 in M.

Program:

M+

x²

Kn 3

Kn 2

Kn 1

Example:

f(x) = 0.3 × x² + 4 × x – 2.01

Start with x = 1

0.3 STO 3

4 STO 2

-2.01 STO 1

1-1 = 0 x→M

Run the program:

f(1) = 2.29

f(2) = 7.19

f(3) = 12.69

f(4) = 18.79

f(5) = 25.49

Geometric Mean

This program calculates the geometric mean (Π(x_i)^(1/n)) by the formula:

GM = 1/n × Σ(ln x_i) (x≠0)

This will require two program slots, so I’m using program slots 1: and 2:.

Memory registers used:

K1 = Σ(ln x_i)

M = n

Steps:

1. Store 0 to memory M (x→M) and memory 1 (STO 1)

2. Enter x_i and press 1:. Continue until you enter all the data. The number of data points is shown.

3. Press 2: to get the geometric mean.

Program 1:

ENT (enter a valid number)

Kn 1

STO 1

M+

Program 2:

1/x

Kn 1

e^x

Example:

Find the geometric mean of 4, 9, 3, 7, 2, 8, 8, 5, and 6. 9 data points.

0 x→M, 0 STO 1

4 [1:], 9 [1:], 3 [1:], 7 [1:], 2 [1:], 8 [1:], 8 [1:], 5 [1:], 6 [1:]

[2:]

Result (geometric mean): 5.2254102087

3D Vectors: Norm of Two Vectors, Dot Product, Angle between Vectors

For this, I presume that the calculator is set to the desired angle setting (DRG). For the example, I have the EL-512 set to degree mode.

Store the vectors as follows:

First vector: [ register 1, register 2, register 3 ]

Second vector: [ register 4, register 5, register 6 ]

The program returns four values:

Norm of the first vector, stored in register 7

Norm of the second vector, stored in register 8

Dot product, stored in registered in M

Angle between two vectors, stored in register 9

Program:

Kn 1

↕

Kn 2

→rθ

↕

Kn 3

→rθ

STO 7

LOOK

Kn 4

↕

Kn 5

→rθ

↕

Kn 6

→rθ

STO 8

LOOK

Kn 1

Kn 4

x→M

Kn 2

Kn 5

M+

Kn 3

Kn 6

M+

LOOK

(

Kn 7

Kn 8

)

cos⁻¹

STO 9

Example:

First vector: [ 70, 64, 36 ]

Second vector: [ 55, 18, 94 ]

Results:

Norm of first vector: 101.4494948

Norm of second vector: 110.3856875

Dot product: 8386

Angle: 41.50953299°

Hope you enjoyed this trip down memory lane. Did you have or do you have a Sharp EL-512 or any similar calculator?

Eddie

All original content copyright, © 2011-2025. Edward Shore. Unauthorized use and/or unauthorized distribution for commercial purposes without express and written permission from the author is strictly prohibited. This blog entry may be distributed for noncommercial purposes, provided that full credit is given to the author.

Spotlight: Commodore P50

Quick Facts

Model: P50

Company: Commodore

Timeline: 1978

Type: Scientific, Programming

Memory: 24 Steps

Order of Operations? No

Battery: 1 x 9-volt battery

Memory Registers: 1

Screen: 8 digits, red LED lights

Manual: www.wass.net/manuals/Commodore%20P50.pdf

From Kate Wasserman, Ph. D.’s website: https://www.wass.net/

This is my first Commodore calculator. The purchase included the calculator a manual, which is available from Kate Wasserman’s website above.

Calculating With the P50

Even though the P50 is a larger sized calculator, the calculator feels light weight. The keys are a pleasure to press.

The set of the P50’s functions is a set of basic of scientific calculators:

* Arithmetic functions

* 1/x, x^2, √x. The power function is missing.

* Logarithmic and exponential functions: log, 10^x, ln, e^x

* Trigonometric Functions: sin, cos, tan, arcsin, arccos, arctan, π key.

* Factorial of positive integer: [ n! ]

* Integer part: [ INT ]

* Memory keys: store, recall, product, sum, exchange. We only get one memory register on the P50.

Every function is a primary key except the inverse the inverse trigonometric functions, which are accessed by the [ arc ] key first.

The P50 operates in Chain mode. That is, operations happen in the order of the keys pressed, without regard to the order of operations.

Example:

9 [ × ] 7 [ + ] 8 [ = ] returns 71.

8 [ + ] 9 [ × ] 7 [ = ] returns 119.

There are no parenthesis keys, hence for more complex calculations, the use of the memory key is needed.

Powers and Roots

The P50 is missing the power function. The manual suggests that powers are calculated by the following keystroke sequence:

y^x: y [ ln ] [ × ] x [ = ] [ e^x ]

y^(1/x): y [ ln ] [ × ] x [ 1/x ] [ = ] [ e^x ]

Alternatively:

y^x: y [ log ] [ × ] x [ = ] [ 10^x ]

y^(1/x): y [ log ] [ × ] x [ 1/x ] [ = ] [ 10^x ]

Example:

5^8: 5 [ ln ] [ × ] 8 [ = ] [ e^x ]; returns 390,625

5^(1/8): 5 [ ln ] [ × ] 8 [ 1/x ] [ = ] [ e^x ] returns 1.2228445.

Other function sequences:

Absolute Value, abs(x): [ x^2 ] [ √x ]

4^th Power, x^4: [ x^2 ] [ x^2 ]

Cube, x^3: [ STO ] [ x^2 ] [ x^2 ] [ ÷ ] [ RCL ] [ = ] (memory is used)

Sign Function, x ≠ 0, sgn(x): [ STO ] [ x^2 ] [ √x ] [ ÷ ] [ RCL [ = ] (memory is used)

Fraction Part, frac(x): [ STO ] [ - ] [ RCL ] [ INT ] [ = ] (memory is used)

Programming

The P50 has a 24-step capacity. There are no merged keystrokes with exceptions:

* The arcsin, arccos, and arctan key sequences ( [ arc ] [ sin ], [ arc ] [ cos ], [ arc ] [ tan ]) are merged.

* The [ GOTO ] key is followed by a two digit address. In this case any steps 0 through 9 are preceded by a zero (00 -09).

The low amount of programming steps and the one memory register to work with, the P50 programming module is good for short, quick repeated calculations. The programming keys available are:

[ lrn ]: Learn/(Run) Mode Toggle. In run mode you are only shown the step number and nothing else.

[ R/S ]: Run/Stop

[ SSTP ]: Single Step key. However, it only works in run mode, executing program steps one step at a time. This is the most annoying quirk of the P50, almost making it programming in the blind calculator. There are no key codes with each step, and they really should be.

[ GOTO ] ##: Directs the P50 to go to step 00-23. The two digit number after a GOTO counts as one step.

There are three skip functions. If the test is true, the program either:

* Skips the next step or

* Skips the next two steps if the step that follows the test is a GOTO.

[ SKZ ]: Skip if the number in the display is zero. (skip if x = 0)

[ SKN ]: Skip if the number in the display is negative. (skip if x < 0)

[ SKP ]: Skip if the number in the display is positive or zero. (skip if x ≥ 0)

In order for the program to stop and display results and reset for the next calculation, we need the following sequence of steps:

R/S

GTO 00

Otherwise, the program could run unintentionally forever.

There is no clear program button, but programs are not kept when the P50 is turned off.

P50: Sample Programs

Round to the nearest hundredths (2 decimal places)

INT

R/S

GTO

Examples:

36.728 → 36.73

54.616 → 54.62

40.303 → 40.30 (display shows 40.3)

Permutation

nPr = n! / (n – r)!

STO

R/S

1/x

RCL

R/S

GTO

To Run: (GTO 00): n R/S r R/S nPr

Examples:

n = 20, p = 8: 5.0791104 E09 (5,079,110,400)

n = 12, p = 6: 665,280

n = 13, p = 7: 8,648,640

Volume of a Sphere

V = 4 * π * r^3 / 3

STO

x^2

RCL

R/S

GTO

Examples:

r = 11.1: 5,728.7193

r = 6: 904.77868

r = 10: 4,188.7902

Pseudo Random Number Generator

#_i = frac( (π + #_i) ^ 5) = M – int (M) (where M = e^( 5 * ln (#_i + π))

e^x

INT

R/S

GTO

To run: seed R/S, R/S, R/S, ….

Examples:

0.552 → 0.4561281 → 0.7501096 → 0.6846062

0.838 → 0.1437699 → 0.7511575 → 0.8871519

Modulus of Positive Numbers

a > 0, b > 0, a mod b = a – int(a / b) * b

R/S

STO

INT

RCL

R/S

GTO

To run: a R/S b R/S result

Examples:

19 mod 7 = 5

288 mod 17 = 16

Eddie

30 + 10 = 40

RPN with HP 15C & DM32: Stack Register Arithmetic

Got a treat for today folks. First...

14 YEARS!!

On the 16^th, it will be 14 years since my blog started!!!! Thank you so much for your support – the blog is one of my joys of life.

Today is another installment of RPN with HP 15C & DM32, I hope you are enjoying this new monthly series, currently every second Saturday of the month.

Stack Register Arithmetic

As we know, nearly all Hewlett Packard (HP) and I think all Swiss Micros (SM) calculators that operate on Reverse Polish Notation (RPN) or Reverse Polish Lisp (RPL, think HP 48 and 50g), a feature that we can calculate an arithmetic operation (+, -, ÷, ×) directly on any number stored in any memory register. It’s a very handy feature indeed.

On the HP 41C, DM41, HP 42S, and DM42 series of calculators, that ability extend to the stack registers themselves (X, Y, Z, T, L (LastX)). To do this, press [ STO ], the required arithmetic operation, the decimal point [ . ], and the appropriate key.

Example:

The current stack is set as:

T: 11

Z: 16

Y: 10

X: 5

Note the 5 in the X stack. We can use the contents of the X stack to do operations on the other levels without “disturbing” the other levels.

Add 5 to stack Z without having to disturb the stack. ST+ Z (41), STO+ ST Z (42) returns:

T: 11

Z: 21

Y: 10

X: 5

Note that the entire stack except Z remains the same.

Multiply stack T by 5. 5 is in the X stack already. ST* T (41), STO× ST T (42) returns:

T: 55

Z: 21

Y: 10

X: 5

Pretty neat, right?

In summary:

STO+ SL: new SLV= old SLV + X

STO- SL: new SLV = old SLV – X

STO× SL: new SLV = old SLV × X

STO÷ SL: new SLV = old SLV ÷ X

where:

X = value in stack level X (display on one-line calculators)

SLV = stack value level (X, Y, Z, T, L)

The 15C and 32S series do not have a native way to do this, but today I will present a way to mimic these powerful stack storage arithmetic on levels X, Y, Z, and T. Most of them will not require the use of an outside memory register (i.e. R0 or R1 for the 15C series, or A or Z for the 32S series).

These techniques were tested on a Hewlett Packard HP 15C and Swiss Micros DM32. They probably would work on the HP 12C (or equivalent) as well, just substitute the roll up (R↑) with three roll down (R↓ R↓ R↓) commands when encountered.

FYI, the 42 series also has recall arithmetic on stack levels, which returns on stack X.

The Algorithms

For the following algorithms, let {OP} stand for the arithmetic operation (+, -, ×, ÷). Let the hash symbol, {#}, stack for a register of your choice (i.e. R0 for 15 or A for 32).

Storage Arithmetic on Stack X

R↑

STO {#}

R↓

ENTER

{OP}

RCL {#}

R↓

Stack Illustration with STO+ X (it will be similar with the rest of the arithmetic operations)

t	z	z	t	z	z	z	t
z	y	y	z	y	z	y	z
y	x	x	y	x	y	x + x	y
x	t	t	x	x	x + x	t	x + x
START	R↑	STO {#}	R↓	ENTER	+	RCL {#}	R↓

Shortcuts:

STO- X: Clx

STO× X: x^2 (specifically, the square function)

The next set will not require a separate memory register.

Example:

40	30	30	40	30	30	30	40
30	20	20	30	20	30	20	30
20	10	10	20	10	20	20	20
10	40	40	10	10	10 + 10 = 20	40	20
START	R↑	STO {#}	R↓	ENTER	+	RCL {#}	R↓

Storage Arithmetic on Stack Y

This is by far the easiest.

{OP}

LAST X

Stack Illustration with STO+ Y (it will be similar with the rest of the arithmetic operations)

t	t	t
z	t	z
y	z	y + x
x	y + x	x
START	+	LAST X

Example:

40	40	40
30	40	30
20	30	30
10	20 + 10 = 30	10
START	+	LAST X

Storage Arithmetic on Stack Z

x<>y

R↓

{OP}

LAST X

R↑

x<>y

Stack Illustration with STO+ Z (it will be similar with the rest of the arithmetic operations)

t	t	y	y	y	t	t
z	z	t	y	t	z +x	z + x
y	x	z	t	z + x	x	y
x	y	x	z + x	x	y	x
START	x<>y	R↓	+	LAST X	R↑	x<>y

Example:

Storage Arithmetic on Stack T

R↑

x<>y

{OP}

LAST X

x<>y

R↓

Stack Illustration with STO+ T (it will be similar with the rest of the arithmetic operations)

t	z	z	z	z	z	t + x
z	y	y	z	y	y	z
y	x	t	y	t + x	x	y
x	t	x	t + x	x	t + x	x
START	R↑	x<>y	+	LAST X	x<>y	R↓

Example:

Until next time,

Eddie